Ultrastructural localization of calcium ions in ram spermatozoa before and after cold shock as demonstrated by a pyroantimonate technique

Ram spermatozoa were subjected to cold shock before fixation in pyroantimonate-osmium. Ultrathin sections revealed an electron-dense particulate precipitate in association with the cells. The precipitate was shown to be related to the presence of calcium by exposure of the material to EGTA which reduced or completely eliminated the deposits. In the acrosome region, very little precipitate was evident when the plasma membrane was intact. Cold shock resulted in the disruption of the plasma membrane. When the acrosome remained intact, precipitate was concentrated just anterior to the equatorial segment, but many cells also had acrosomal disruption and then a more even distribution of precipitate was seen on the outer acrosomal membrane. Precipitate was rarely visible within or beneath the acrosome. Post-acrosomally, calcium pyroantimonate deposits were frequently present in the dense lamina beneath the plasma membrane and these became more intense after cold shock. Midpiece sections revealed a few large granules beneath the plasma membrane and a fine particulate precipitate within mitochondria. Similarly, the fine precipitate was also associated with the outer dense fibres in midpieces and tails. Cold shock did not apparently increase the extent or intensity of precipitates in these sites.     

The status of acrosomal caps of hamster spermatozoa immediately before fertilization in vivo

Adult female golden hamsters were induced to superovulate. When they were mated several hours prior to ovulation or artificially inseminated about the time of ovulation, nearly 100% of their eggs were subsequently fertilized monospermically. During the progression of fertilization when the eggs were still surrounded by compact cumulus oophorus, the contents of the ampullary region of the oviducts were collected and spermatozoa moving in the ampullary fluid, within the cumulus and on/in the zonae pellucidae of unfertilized eggs, were examined by light and electron microscopy to evaluate the status of their acrosomal caps. Most spermatozoa swimming in the ampullary fluid had apparently intact acrosomal caps, while the vast majority moving within the cumulus had distinctly modified acrosomal caps. Most spermatozoa that had passed through the cumulus and reached the zona surfaces had remnants of their acrosomal caps (“acrosomal ghosts”). When the ghosts were present around the sperm heads on the zona, the heads pivoted about a point roughly corresponding to the places where the ghosts were located. The ghosts seemed to firmly attach to the zona surfaces, then were split open by the sperm heads and left behind as the sperm heads advanced into the zona. A few spermatozoa on the zona surfaces had no acrosomal ghosts (at least not detectable by light microscopy). In this case, the sperm head pivoted about either the inner acrosomal membrane or the equatorial segment of the acrosome. In no instance were spermatozoa with intact acrosomal caps found on zona surfaces. We infer from these observations that most spermatozoa in vivo initiate their acrosome reactions while they are advancing through the cumulus. When they arrive at the zona surfaces, acrosomal ghosts are generally present on the sperm heads. These ghosts appear to hold sperm heads to zona surfaces as well as to restrict the direction of advancement of sperm head through the zona. In a minority of cases, ghostless spermatozoa reach the zona surfaces. As these spermatozoa appear to be able to penetrate the zona successfully, structures other than the acrosomal ghost (ie, the inner acrosomal membrane and the plasma membrane over the equatorial segment of the acrosome) may also attach to zona surfaces before spermatozoa penetrate into the zona.     

Ultrastructure of Octodon degus spermatozoon with special reference to the acrosome

The ultrastructure of spermatozoa from the cauda epididymidis and vas deferens of Octodon degus-a Chilean hystricomorph rodent-is presented. The head of spermatozoa measured 7.7 micrometer long by 5.9 micrometer wide and the tail was 41 micrometer long. The head was flattened dorso-ventrally and ovate in outline. The acrosome was the most distinctive feature of O. degus spermatozoa. In a frontal view of the head, the rim of the acrosome surrounding the nucleus had the shape of an inverted U. The acrosomal region covering the plane of the flattened head exhibited dome-shaped protrusions. Transverse or sagittal sections of acrosomal protrusions showed that the plasma membrane and outer acrosomal membrane were evaginated, while the inner acrosomal membrane followed the contour of the nucleus. The protrusions were not distributed at random and they were absent in the equatorial segment and in the rim of the acrosome. In frontal views, near the boundary between the acrosome and post-acrosomal region, fine rods about 170 nm long ran obliquely on the caudal part of the equatorial segment. Behind the same boundary, the post-acrosomal region showed a serrated border. Phosphotungstic acid treatment at pH 0.3 produced staining at the surface of the sperm as well as within a superficial layer of the marginal thickening of the acrosome and on the acrosomal protuberances.     

Substructure of a cytoskeletal complex associated with the hamster sperm acrosome

Whole mount and thin section preparations of intact and selectively disrupted hamster spermatozoa revealed an organized array of cytoplasmic filaments associated with specific regions of the acrosome. The filaments were localized along the ventral surface of the spermatozoon and extended from its tip, distally to the anterior margin of the equatorial segment. Individual filaments were 11-13 nm in diameter and they were aligned parallel to one another to form a two-dimensional sheet oriented in the long axis of the spermatozoon. The filament complex adhered preferentially to the cytoplasmic surface of the outer acrosomal membrane rather than the plasma membrane. Examination of disrupted spermatozoa revealed that the distribution of this cytoskeletal assembly correlated with the distribution of a specific acrosomal matrix component. The possible role of this complex in the acrosome reaction or in the organization of acrosomal matrix domains is discussed.     

Localization of intracellular calcium during the acrosome reaction in ram spermatozoa

Calcium was identified by a pyroantimonate-osmium fixation technique in ram spermatozoa undergoing a spontaneous acrosome reaction induced by incubation of diluted semen at 39°C. Intracellular calcium was only detected in diluted spermatozoa and increased in amount and distribution over 4 hr At 4 hr, the majority of the spermatozoa displayed ultrastructural evidence of an acrosome reaction. Calcium was initially evident on the outer acrosomal membrane in multiparticulate clusters, which were seen to be located on scalloped crests of acrosomal membrane as fusion developed; it was also located in the region of the acrosomal ridge beneath the outer acrosomal membrane. Vesiculation commenced just anterior to the equatorial segment and proceeded anteriorly. As vesiculation advanced, calcium particles became associated with the periphery of the vesicles attached in the region of the fusion between the two membranes, but were never seen inside the vesicles. The equatorial segment was not labelled until much later in the reaction, at which time calcium particles were also evident on the nuclear membrane; vesiculation of the equatorial segment was also noted at this time. Dense labelling of the postacrosomal dense lamina was seen in all incubated spermatozoa. At the anterior margin of this structure the labelling was seen to be in a “sawtooth” arrangement. The disposition of the calcium both temporally and spatially is discussed in relation to its possible mechanisms in bringing about membrane fusion. © 1995 Wiley-Liss, Inc.     

Progesterone treatment of boar spermatozoa improves male pronuclear formation after intracytoplasmic sperm injection into porcine oocytes

Boar spermatozoa were prepared for intracytoplasmic sperm injection (ICSI) by two different treatments to facilitate sperm chromatin decondensation and improve fertilisation rates after ICSI in pigs: spermatozoa were either frozen and thawed without cryoprotectants, or treated with progesterone. Morphological changes of the sperm heads after the treatments were examined and then the activation of oocytes and the transformation of the sperm nucleus following ICSI were assessed. After freezing and thawing, the plasma membrane and acrosomal contents over the apical region of sperm head were lost in all the spermatozoa. Following treatment with 1 mg/ml progesterone, the acrosome reaction was induced in 61% of spermatozoa. After injection of three types of spermatozoa, non-treated spermatozoa and progesterone-treated (i.e. acrosome-reacted) spermatozoa induced oocyte activation, but frozen-thawed spermatozoa induced oocyte activation at a significantly lower rate. Sixty-two per cent of sperm heads remained orcein-negative for 6 h, however, resulting in delayed sperm chromatin decondensation and low male pronuclear formation in the oocytes injected with a non-treated spermatazoon. Since the treatments of freezing and thawing and progesterone for spermatozoa accelerated the initial change in sperm chromatin and the latter treatment induced oocyte activation earlier, it is considered that the delay in oocyte activation and decondensation of sperm chromatin after injection of non-treated spermatozoa is caused by the existence of the sperm plasma membrane. These results show that progesterone treatment efficiently induces the acrosome reaction in boar spermatozoa without destroying their potency for oocyte activation, and the induction of the acrosome reaction results in the promotion of male pronuclear formation after ICSI.     

Difference in the Manner of Association of Acrosome-Intact and Acrosome-Reacted Hamster Spermatozoa with Egg Microvilli as revealed by Scanning Electron Microscopy

Scanning electron microscopy was employed to examine the manner of association between in vitro capacitated spermatozoa and zona-free eggs of the hamster. Spermatozoa with intact acrosomes, which were unable to fuse with eggs, were seen in general associated with egg microvilli in the region of the acrosomal cap. Acrosome-reacting spermatozoa were seen associated with egg microvilli with the dissociating acrosomal caps. Acrosome-reacted spermatozoa, which were able to fuse with eggs, generally associated with egg microvilli by the equatorial segment and the anterior portion of the postacrosomal region. It is inferred that the completion of the acrosome reaction signals changes in the plasma membrane over the equatorial segment of the acrosome and the anterior area of the postacrosomal region which give it a greater affinity to and fusibility with the oolemma.     

Differential binding of gold-labeled zona pellucida glycoproteins mZP2 and mZP3 to mouse sperm membrane compartments.

Egg zona pellucida glycoproteins mZP3 and mZP2 serve as primary and secondary sperm receptors, respectively, during initial stages of fertilization in mice [Wassarman (1988) A. Rev. Biochem. 57, 415-442]. These receptors interact with complementary egg-binding proteins (EBPs) located on the sperm surface to support species-specific gamete adhesion. Results of whole-mount autoradiographic experiments suggest that purified egg mZP3 and mZP2 bind preferentially to acrosome-intact (AI) and acrosome-reacted (AR) sperm heads, respectively [Bleil and Wassarman (1986) J. Cell Biol. 102, 1363-1371]. Here, we used purified egg mZP2, egg mZP3 and fetuin, which were coupled directly to colloidal gold ('gold-probes'), to examine binding of these glycoproteins to membrane compartments of AI and AR sperm by transmission electron microscopy. mZP3 gold-probes were found associated primarily with plasma membrane overlying the acrosomal and post-acrosomal regions of AI sperm heads. They were also found associated with plasma membrane overlying the post-acrosomal region of AR sperm heads. mZP2 gold-probes were found associated primarily with inner acrosomal membrane of AR sperm heads, although some gold was associated with outer acrosomal membrane of AI sperm that had holes in plasma membrane overlying the acrosome. Fetuin gold-probes, used to assess background levels of binding, were bound at relatively low levels to plasma membrane and inner acrosomal membrane of AI and AR sperm, respectively. None of the gold-probes exhibited significant binding to sperm tails, or to red blood cells and residual bodies present in sperm preparations. These results provide further evidence that mZP2 and mZP3 bind preferentially to heads of AR and AI sperm, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro characteristics of canine spermatozoa subjected to two methods of cryopreservation

The in vitro viability of canine spermatozoa was evaluated after freezing-thawing using the Andersen method, and the commercial CLONE method. These methods differ in the extenders used, number of dilution steps, and equilibration times as well as in both freezing and thawing techniques and rates. Insemination with semen frozen-thawed by either method gives high whelping rates in practice, implying that dog spermatozoa can retain their fertilizing ability after being subjected to widely different preservation methods. The in vitro viability of spermatozoa processed by these methods has not been previously evaluated in detail. Three ejaculates were collected from each of 5 fertile dogs. Each ejaculate was divided into 2 parts and frozen in medium straws according to the 2 methods. Two straws were thawed and examined from each freezing batch. Sperm motility was assessed in the undiluted semen, and in frozen-thawed semen immediately after thawing, and after storage for 3, 6 and 24 h at room temperature (Straw 1) or 1, 2 and 3 h at 37 degrees C (Straw 2, thermoresistance test). The integrity of the sperm plasma membrane was evaluated in undiluted, in equilibrated (diluted and chilled), and in frozen-thawed spermatozoa using fluorophore probes. The acrosome morphology of frozen-thawed spermatozoa was assessed using a commercial stain (Spermac). Motility immediately after thawing was significantly higher with the CLONE method (75.3% [SD = 4.0] for Straw 1 and 73.7% [SD = 3.2] for Straw 2) than with the Andersen method (70.0% [SD = 5.1] and 69.7% [SD = 3.2]). Motility decreased during storage after thawing. Spermatozoa frozen-thawed using the CLONE method showed a significantly lower thermoresistance. The proportion of spermatozoa with intact plasma membrane was not affected by the equilibration procedure used with either method but was significantly decreased (P < 0.001) after thawing with both methods. The percentage of spermatozoa exhibiting changes thought to represent different stages of acrosomal degradation, was 45.7% (SD = 5.3) using the Andersen method and 44.1% (SD = 9,4) using the CLONE method. Both cryopreservation methods thus resulted in high initial post-thaw sperm motility and membrane integrity but low thermoresistance, and under both methods a large proportion of sperm cells were undergoing acrosomal degradation. The methods differed significantly in terms of their effect on sperm motility but not on plasma membrane integrity or acrosomal morphology.     

Comparative scanning electron microscope study of boar,bull and ram spermatozoa

The comparative ultrastructure of ejaculated boar, bull and ram spermatozoa is studied by scanning electron microscopy. After washing, the spermatozoa are fixed in glutaraldehyde or im picric acid-formaldehyde-glutaraldehyde mixture. Samples are prepared either by critical point drying (Freon) on Millipore filters or by air drying on glass cover slips. In all the species studied, three regions may be distinguished in the paddle-shaped head of the sperm: an anterior segment (surrounded by the marginal thickening) and an equatorial segment constituting together the acrosome, and the postacrosomal region. Most of the feature of the postacrosomal lamina described in transmission electron microscopy are visible through the plasma membrane, particularly after air drying. The surface morphology of the neck and of the different segments of the flagellum is also evident. Some species differences are encountered, e.g. rough surface of acrosome and absence of serrations in postacrosomal lamina of boar spermatozoa only. The techniques employed result in good general morphology and fine resolution of surface detail of the sperm samples; they also permit analysis of spermatozoa treated by freezing or submitted to acrosomal extraction.     

Cryopreservation, actin localization and thermotropic phase transitions in ram spermatozoa

The effects of controlled stress, i.e. cooling, upon the distribution of actin in ram spermatozoa were examined to investigate the hypothesis that cytoskeletal proteins are involved in the maintenance of sperm plasma membrane integrity. The normal distribution of actin on the spermatozoon was initially determined. A monoclonal antibody (IgM) interacted exclusively with the post-acrosomal region and the principal piece of the flagellum. By the use of a polyclonal antibody, actin was detected on the acrosome (excluding the equatorial segment), the post-acrosomal region and the whole of the flagellum. The actin was present in its non-filamentous form. Spermatozoa fixed at 39 degrees C and then treated for the immunofluorescent detection of actin with the monoclonal antibody were mostly unstained (proportion stained = 4.4% (+/- 1.6; s.e.m.); n = 8 ejaculates). Provided spermatozoa were permeabilized by greater than 0.025% Triton X-100 before immunofluorescence, actin was localized in the postacrosomal region of all sperm heads, and to a minor extent on the principal piece of the flagellum. Use of the polyclonal antibody confirmed that the post-acrosomal antigen was unmasked by detergent treatment. Slow cooling, over 2-h periods to various temperatures between 5 and 15 degrees C, also induced an increase in the proportion of cells showing post-acrosomal actin immunoreactivity. Cooling through the temperature range 15 to 10 degrees C markedly increased the proportion of immunoreactive cells (mean +/- s.e.m.; 12 +/- 4.5% at 15 degrees C; 27 +/- 4.5% at 10 degrees C; n = 4 ejaculates). Further cooling to 5 degrees C failed to elicit increased staining. Ultrastructural examination of cooled spermatozoa confirmed that a subpopulation of spermatozoa exhibited post-acrosomal actin immunoreactivity after cooling. These results are compatible with the suggestion that actin fulfills a stabilizing function in spermatozoa.     

Autoradiographic visualization of the mouse egg's sperm receptor bound to sperm

The extracellular coat, or zona pellucida, of mammalian eggs contains species-specific receptors to which sperm bind as a prelude to fertilization. In mice, ZP3, one of only three zona pellucida glycoproteins, serves as sperm receptor. Acrosome-intact, but not acrosome-reacted, mouse sperm recognize and interact with specific O- linked oligosaccharides of ZP3 resulting in sperm-egg binding. Binding, in turn, causes sperm to undergo the acrosome reaction; a membrane fusion event that results in loss of plasma membrane at the anterior region of the head and exposure of inner acrosomal membrane with its associated acrosomal contents. Bound, acrosome-reacted sperm are able to penetrate the zona pellucida and fuse with the egg's plasma membrane (fertilization). In the present report, we examined binding of radioiodinated, purified, egg ZP3 to both acrosome intact and acrosome reacted sperm by whole-mount autoradiography. Silver grains due to bound 125I-ZP3 were found localized to the acrosomal cap region of heads of acrosome-reacted sperm. Under the same conditions, 125I-fetuin bound at only bacKground levels to heads of both acrosome-intact and - reacted sperm, and 125I-ZP2, another zona pellucida glycoprotein, bound preferentially to acrosome-reacted sperm. These results provide visual evidence that ZP3 binds preferentially and specifically to heads of acrosome intact sperm; properties expected of the mouse egg's sperm receptor.     

Membrane differentiations in spermatozoa of the squid,Loligo pealeii

Regional differences in the structure of the plasma membrane and acrosome membrane of squid spermatozoa were studied by freeze-fracture and thin section electron microscopy. In regions of close apposition the plasma membrane and acrosome membrane are adjoined to one another by regularly spaced linkages. These linkage sites, overlie a set of fibers located at the inner face of the acrosomal membrane. The acrosomal fibers terminate in a layer of granular material located at the base of the acrosome. Detergent treatment of sperm releases the fibers and granular material as an interconnected complex. Freeze-fracture replicas reveal a random arrangement of intramembranous particles in the plasma membrane over the sperm head and linear aggregates of intramembranous particles in the acrosomal membrane. Several regional differences in the structure of the flagellar plasma membrane are present. The thickness of the glycocalyx is progressively reduced distally along the flagellum. Freeze-fracture replicas show evenly spaced linear arrays of intramembranous particles which extend parallel t o the flagellar long axis. Examination of spermatozoa extracted to disrupt flagellar geometry suggest that the dense fiber-doublet microtubule complexes are attached to the plasma membrane. The possible functional role of these membrane differentiations and their relationship t o membrane structures in mammalian spermatozoa are discussed.     

Sperm surface changes during the acrosome reaction as observed by freeze-fracture

The mammalian acrosome reaction is an exocytotic process that can be analyzed by the technique of freeze-fracture; only sperm cells capacitated in vitro or treated to elicit the acrosome reaction in vitro have been studied, and all pictures published are from material fixed before freezing. All the authors point out the appearance of particle-free areas in the plasma membrane of the acrosomal region during capacitation and before any fusion. This is interpreted as an increase in membrane fluidity as suggested by studies on membrane lipid composition in guinea-pig sperm. We have recently described the induced acrosome reaction in ram spermatozoa. Fusion starts at the limit of the anterior and equatorial segments and progresses forward in the anterior segment along ramified paths, resulting in a fenestration gradient of the acrosomal cap. Fusion propagation may be controlled by fluidity increase in the plasma membrane of the anterior segment, and it is probably inhibited in the equatorial segment by the ordered structure of the acrosomal membrane.     

Biochemical characterization of the PH-20 protein on the plasma membrane and inner acrosomal membrane of cynomolgus macaque spermatozoa

Preparations of sperm membranes (plasma membranes and outer acrosomal membranes) and denuded sperm heads were isolated from macaque sperm, and the PH-20 proteins present were characterized by Western blotting, hyaluronic acid substrate gel analysis, and a microplate assay for hyaluronidase activity. Because we have shown previously that PH-20 is located on the plasma membrane and not on the outer acrosomal membrane, the PH-20 in the membrane preparations was presumed to be plasma membrane PH-20 (PM-PH-20). PM-PH-20 had an apparent molecular weight of 64 kDa and the optimum pH for its hyaluronidase activity was 6.5. The PH-20 associated with denuded sperm heads was localized by immunogold label to the persistent inner acrosomal membrane (IAM) and was presumed to be IAM-PH-20, which included a major 64 kDa form and a minor 53 kDa form. The 53 kDa form was not detected in extracts of denuded sperm heads from acrosome intact sperm that were boiled in nonreducing sample buffer, but was present in extracts of sperm heads from acrosome reacted sperm and in the soluble material released during the acrosome reaction, whether or not the samples were boiled. Substrate gel analysis showed that the hyaluronidase activity of the 53 kDa form of PH-20 was greatest at acid pH, and this activity was probably responsible for the broader and lower optimum pH of IAM hyaluronidase activity. When hypotonic treatment was used to disrupt the sperm acrosome and release the acrosomal contents, less than 0.05% of the total hyaluronidase activity was released. The PH-20 protein released by hypotonic treatment was the 64 kDa form and not the 53 kDa form, suggesting that its source might be the disrupted plasma membranes. Our experiments suggest that the soluble form of hyaluronidase, which is released at the time of the acrosome reaction, is derived from the IAM. This soluble hyaluronidase is composed of both the 64 kDa form and 53 kDa form of PH-20. The 53 kDa form appears to be processed from the 64 kDa form at the time of the acrosome reaction. Mol. Reprod. Dev. 48:356–366, 1997. © 1997 Wiley-Liss, Inc.     

Gamete membrane fusion in hamster spermatozoa with reacted equatorial segment

Mammalian spermatozoa must undergo many changes to be able to fertilize the oocyte. One of these changes, the acrosome reaction, has been established as a requisite for gamete membrane fusion to occur; it consists of the fusion and vesiculation of the sperm plasma membrane with the outer acrosomal membrane of the principal segment of the acrosome. Reaction of the equatorial segment has occasionally been observed. The objective of the present work was to determine whether the presence of the sperm plasma membrane over the equatorial segment is necessary for gamete membrane fusion to occur. Golden hamster spermatozoa were capacitated in vitro in TAPL 10K, and the maximum possible percentage of acrosome reaction was determined at 82.79% + 1.69% SD (P = 0.27; r = 0.21). Ultrastructural studies showed that 93.6% of the reacted spermatozoa in this population had their principal and equatorial segments reacted. The fertilizing ability of these spermatozoa was assayed using zona-free hamster oocytes. The percentage of fertilized ova obtained was 98.8% (308/312). Ultrastructural studies snowed the presence of spermatozoa with reacted equatorial segment inside the cytoplasm of immature oocytes. The evidence presented in this work demonstrates that the plasma membrane of spermatozoa with reacted equatorial segment retains its ability to fuse with the oocyte.     

Fucoidin inhibits attachment of guinea pig spermatozoa to the zona pellucida through binding to the inner acrosomal membrane and equatorial domains

Our previous study has shown that fucoidin, an algal heteropolysaccharide, is a potent inhibitor of sperm-zona binding in the guinea pig, hamster and human. To visualize the surface site of fucoidin binding, a biotinated derivative (B-Fuc) of the native fucoidin was prepared. B-Fuc retained the inhibitory activity and was used in conjunction with FITC-avidin to localize its binding sites on guinea pig spermatozoa using fluorescence microscopy. In living acrosome-reacted spermatozoa, B-Fuc bound predominantly to the inner acrosomal membrane and equatorial segment domains. The binding was effectively competed by a 10-fold excess of native fucoidin, but not by a 10-fold excess of heparin or a 20-fold excess of biotinated normal rabbit serum IgG. B-Fuc binding patterns on dead spermatozoa were quite different from that of living spermatozoa. The post-acrosomal region, rather than the inner acrosomal membrane and equatorial domains, was intensely labeled. This indicates the importance of using living cells in assessing true surface binding sites whenever possible. We conclude that the inner acrosomal membrane and/or equatorial domains are critical for zona binding in the guinea pig.     

Specific labelling by peanut agglutinin of the outer acrosomal membrane of the human spermatozoon

Experiments to bind fluorescein-conjugated Arachis hypogea (peanut) agglutinin (FITC-PNA) to washed human spermatozoa demonstrated that this lectin binds to the acrosome region in air-dried preparations. Since there was no binding when labelling was performed in suspension, and comparable labelling to that seen in air-dried preparations was seen when spermatozoa treated with saponin (to lyse the plasma membrane) were labelled in suspension, the lectin must bind to an intracellular structure, probably the outer acrosomal membrane. This was confirmed by ultrastructural localization of colloidal gold-conjugated lectin in saponin-treated spermatozoa. Treatment of spermatozoa with the detergent Nonidet P-40 caused a marked change in the binding pattern: more spermatozoa showed binding in the equatorial segment of the acrosome with no binding in the anterior cap region. A comparable, less marked, change was seen when spermatozoa were incubated overnight under conditions known to support the capacitation and spontaneous acrosome reactions. Treatment with the calcium ionophore A23187 for 1 h to induce acrosome reactions artificially in uncapacitated spermatozoa resulted in the appearance of patchy acrosome fluorescence. From these experiments it is concluded that PNA binds specifically to the outer acrosomal membrane, and that FITC-PNA-labelling may be used to monitor the human sperm acrosome reaction.     

The equatorial subsegment in mammalian spermatozoa is enriched in tyrosine phosphorylated proteins

The equatorial subsegment (EqSS) was originally identified by atomic force microscopy as a discrete region within the equatorial segment of Artiodactyl spermatozoa. In this investigation, we show that the EqSS is enriched in tyrosine phosphorylated proteins and present preliminary evidence for its presence in mouse and rat spermatozoa. The anti-phosphotyrosine monoclonal antibody (McAb) 4G10 bound strongly and discretely to the EqSS of permeabilized boar, ram, and bull spermatozoa. It also bound to a small patch on the posterior acrosomal region of permeabilized mouse and rat spermatozoa, suggesting that the EqSS is not restricted to the order Artiodactyla. An anti-HSPA1A (formerly Hsp70) antibody recognized the EqSS in boar spermatozoa. Immunogold labeling with McAb 4G10 localized the tyrosine phosphorylated proteins to the outer acrosomal membrane. This was verified by freeze-fracture electron microscopy, which identified the EqSS in three overlying membranes, the plasma membrane, outer acrosomal membrane, and inner acrosomal membrane. In all five species, tyrosine phosphorylated proteins became restricted to the EqSS during sperm maturation in the epididymis. The major tyrosine phosphorylated proteins in the EqSS of boar and ram spermatozoa were identified by mass spectrometry as orthologs of human SPACA1 (formerly SAMP32). Immunofluorescence with a specific polyclonal antibody localized SPACA1 to the equatorial segment in boar spermatozoa. We speculate that the EqSS is an organizing center for assembly of multimolecular complexes that initiate fusion competence in this area of the plasma membrane following the acrosome reaction.     

Phospholipid composition of isolated guinea pig sperm outer acrosomal membrane and plasma membrane during capacitation in vitro

After capacitation of guinea pig spermatozoa in vitro, the plasma membrane was mechanically separated from the spermatozoa in the presence or absence of HgCl₂ and subsequently isolated by density gradient centrifugation. Examination of the spermatozoa by electron microscopy after homogenization in the presence of HgCl₂ revealed that plasma membrane was removed only from the acrosomal region and remained predominately intact posterior to the equatorial segment of the sperm head, as well as the midpiece and tail. In comparison, spermatozoa homogenized under similar buffer conditions but in the absence of HgCl₂ lose the large apical segment of the acrosome and the plasma membrane is removed essentially from the entire cell. If spermatozoa were homogenized in the absence of Hg²⁺, analysis of plasma membrane phospholipid composition revealed a complete loss of lysophosphatidylcholine (LPC) from the plasma membrane after incubation of spermatozoa in minimal capacitating medium (MCM-PL) for 2 hours. Under these culture conditions the addition of Ca²⁺ (5 mM) to the capacitated spermatozoa induced approximately 78 ± 5% (n = 3) of the motile spermatozoa to undergo acrosome reactions while still maintaining sperm motility (80 ± 5%) (n = 3). If the spermatozoa were homogenized in the presence of Hg²⁺, a time course study revealed that plasma membrane LPC loss occurred between 60 and 90 minutes of incubation. This complete loss of LPC was evident when approximately half of the capacitated spermatozoa had undergone acrosome reactions. Incubation of the spermatozoa with the metabolic and acrosome reaction inhibitor, 2-deoxyglucose (10 mM) for 2 hours, maintained the plasma membrane phospholipid composition similar to that in the noncapacitated state. These data provide evidence that changes in the plasma membrane phospholipid composition may be associated with guinea pig sperm capacitation.